Limiting a current

ABSTRACT

In an embodiment, a power-supply controller includes a switching regulator and a current limiter. The switching regulator is configured to generate an input current such that an output voltage is generated in response to the input current and an input voltage, and the current limiter is configured to limit the input current in response to a quantity that is related to a ratio of the output voltage divided by the input voltage. For example, an embodiment of such a power-supply controller may be able to limit the output or load current from a power supply to a set level by limiting the input current in response to a quantity that is related to the ratio (e.g., the boost ratio) of the output voltage to the input voltage.

PRIORITY CLAIM

This application claims priority from provisional patent application No. 61/721,790, filed 2 Nov. 2012, which is incorporated in its entirety herein by reference.

SUMMARY

In an embodiment, a power-supply controller includes a switching regulator and a current limiter. The switching regulator is configured to generate an input current such that an output voltage is generated in response to the input current and an input voltage, and the current limiter is configured to limit the input current in response to a quantity that is related to a ratio of the output voltage divided by the input voltage.

For example, an embodiment of such a power-supply controller may be able to limit the output or load current from a power supply to a defined level in response to a quantity that is related to the ratio of the output voltage to the input voltage. Where the power supply is a boost converter that generates an output voltage having a magnitude that is greater than the magnitude of the input voltage, then this ratio is the boost ratio of the power supply.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram of power supply that includes a power-supply controller, according to an embodiment.

FIG. 2 is a time plot of the input current of the power supply of FIG. 1 while operating in a normal mode, according to an embodiment.

FIG. 3 is a time plot of the switch current of the power supply of FIG. 1 while operating in a normal mode, according to an embodiment.

FIG. 4 is a time plot of both the input and switch currents of the power supply of FIG. 1 while operating in a normal mode, according to an embodiment.

FIG. 5 is a time plot of the switch current of the power supply of FIG. 1 while operating in a current-limiting mode, according to an embodiment.

FIG. 6A is a time plot of the input and output voltages of the power supply of FIG. 1 while operating in a normal mode and while operating in a current-limiting mode, according to an embodiment.

FIG. 6B is a time plot of the input and output currents of the power supply of FIG. 1 while operating in a normal mode and while operating in a current-limiting mode, according to an embodiment.

FIG. 7A is another time plot of the input and output voltages of the power supply of FIG. 1 while operating in a normal mode and while operating in a current-limiting mode, according to an embodiment.

FIG. 7B is another time plot of the input and output currents of the power supply of FIG. 1 while operating in a normal mode and while operating in a current-limiting mode, according to an embodiment.

FIG. 8 is a plot of the boost ratio of the power supply of FIG. 1 versus the duty cycle of the power supply of FIG. 1, according to an embodiment.

FIG. 9 is a diagram of power supply that includes a power-supply controller, according to another embodiment.

FIG. 10 is a diagram of a current-limit-reference generator of the power-supply controller of FIG. 9, according to an embodiment.

FIG. 11A is a time plot of the input and output voltages of the power supply of FIG. 9 while operating in a normal mode and while operating in a current-limiting mode, according to an embodiment.

FIG. 11B is a time plot of the input and output currents of the power supply of FIG. 9 while operating in a normal mode and while operating in a current-limiting mode, according to an embodiment.

FIG. 12A is another time plot of the input and output voltages of the power supply of FIG. 9 while operating in a normal mode and while operating in a current-limiting mode, according to an embodiment.

FIG. 12B is another time plot of the input and output currents of the power supply of FIG. 9 while operating in a normal mode and while operating in a current-limiting mode, according to an embodiment.

FIG. 13 is a diagram of a system that incorporates the power supply of FIG. 9, according to an embodiment.

DETAILED DESCRIPTION

FIG. 1 is a schematic diagram of a boost converter power supply 10, and of a load 12 that is powered by the power supply, according to an embodiment.

The power supply 10 is configured to generate, in a normal operation mode, an output voltage, e.g., a regulated output voltage, V_(out) on a node 14 in response to an input voltage V_(in) on a node 16, and includes a filter inductor 18 having an inductance L, a unidirectional-current component (here a diode) 20, a filter capacitor 22 having a capacitance C, a power-supply controller 24, and a reference node (here a ground node) 26.

The power-supply controller 24 includes a switching regulator 28 configured to generate, or to cause the generating of, input, switch, output, and load currents I_(in), I_(switch), I_(out), and I_(load), and includes a current limiter 30 configured to limit I_(out) and I_(lead) during a current-limiting mode by limiting I_(switch), and, therefore, I_(in), to respective values set by a current-limit reference CL_(ref).

The switching regulator 28 includes an error amplifier 32, a pulse-width-modulation (PWM) controller 34, and a NMOS switching transistor 36. During a normal mode of operation, the error amplifier 32 generates an error signal in response to the regulated output voltage V_(out) and a reference voltage V_(ref), and, in response to the error signal, the PWM controller 34 generates, and adjusts the duty cycle of, a control signal 38, which drives the gate of the transistor 36 so as to regulate V_(out) to a voltage level (e.g., 12 Volts) that is set by V_(ref).

And the current limiter 30 includes a current sensor 40 and a limit comparator 42. During a current-limiting mode of operation caused by, for example, a low-impedance path through, or around, the load 12, if I_(switch) (e.g., the peak or average of I_(switch)) is greater than the current-limit reference CL_(ref), then the comparator 42 generates, at its output, a current-limit signal having a logic-high level that causes the PWM controller 34 to transition the switching-control signal 38 to a logic-low level so as to turn the transistor 36 “off”. Limiting I_(switch) in this manner may prevent damage to, e.g., the transistor 36. And, because limiting I_(switch) inherently limits I_(out) and I_(load), limiting I_(switch) in this manner may also prevent damage to the load 12.

FIG. 2 is a time plot of the input current I_(in) of FIG. 1 while the power supply 10 of FIG. 1 is operating in a normal mode, according to an embodiment.

FIG. 3 is a time plot of the switch current I_(switch) of FIG. 1 while the power supply 10 of FIG. 1 is operating in a normal mode, according to an embodiment.

FIG. 4 is a time plot of both the input current I_(in) of FIG. 2 and the switch current I_(switch) of FIG. 3 while the supply 10 of FIG. 1 is operating in a normal mode, according to an embodiment; I_(in) is shown in dashed line, I_(switch) is shown in solid line, and there I_(in) and I_(switch) are equal is shown in bold dashed line.

Referring to FIGS. 2-4, during a first portion T_(on) of a switching period T of the transistor 36 (FIG. 1)—T_(on) corresponds to the logic-high portion of the control signal 38 of FIG. 1—the transistor conducts the current I_(switch)=I_(in) from V_(in) through the inductor 18. Because the change in current, di/dt, through an inductor equals the voltage across the inductor over the inductance of the inductor, during T_(on), I_(switch)=I_(in) ramps up linearly from a valley level I_(valley) at a time t₀ to a peak level I_(peak) at a time t₁ with a slope of V_(in)/L, where V_(in) is the voltage across the inductor 18 (with the assumption that the voltage drop across the “on” transistor 36 is negligible) and L is the inductance of the inductor.

At the time t₁, the transistor 36 turns “off” such that I_(switch) rapidly decreases to zero and I_(in) begins to decrease with a slope of (V_(out)−V_(in))/L, where V_(out)−V_(in) is the voltage across the inductor 18 (with the assumption that the voltage drop across the diode 20 is negligible).

During a second portion T_(off) of the switching period T of the transistor 36 (FIG. 1)—T_(off) corresponds to the logic-low portion of the control signal 38 of FIG. 1—the transistor conducts no current, and, therefore, I_(switch) remains at zero and I_(in) continues to ramp down at a rate of (V_(out)−V_(in))/L, until a time t₂, which is the beginning of the next normal-mode switching cycle.

FIG. 5 is a time plot of the switch current I_(switch) of FIG. 1 while the power supply 10 is operating in a current-limiting mode, according to an embodiment. The condition causing the power supply 10 to operate in the current-limiting mode may be, e.g., a low-impedance path between the supply output node 14 and the reference node 26 (FIG. 1). Causes of such a low-impedance path can include damage to the load 12, the coupling of an improper load, and a short circuit formed across the load (e.g., from a spilled conductive liquid such as water).

During a first portion T_(on) of the switching period T of the transistor 36 (FIG. 1)—T_(on) corresponds to the logic-high portion of the control signal 38 of FIG. 1—the transistor conducts the current I_(switch) from V_(in) through the inductor 18. Because the change in current di/dt through an inductor equals the voltage across the inductor over the inductance of the inductor, during T_(on), I_(switch) ramps up linearly from I_(valley) at a time t₀ with a slope of V_(n)/L (with the assumption that the voltage drop across the “on” transistor 36 is negligible). But because of the over-current condition, I_(switch) increases to a threshold level at a time t₁; that is, even if the load 12 is such that it would otherwise cause I_(switch) to increase beyond the threshold level to a peak level I_(peak), the current limiter 30 prevents I_(switch) from increasing beyond I_(limit). A designer of the power supply 10 (FIG. 1) typically selects I_(limit) such that the components (e.g., the transistor 36) of the power supply are not damaged while an over-current condition exists.

At the time t₁, the transistor 36 turns “off” such that I_(switch) rapidly decreases to zero.

During the second portion T_(off) of the switching period T of the transistor 36 (FIG. 1)—T_(off) corresponds to the logic-low portion of the control signal 38 of FIG. 1—the transistor conducts no current, and, therefore, I_(switch) remains at zero until a time t₂, which is the beginning of the next current-limiting-mode switching cycle.

Referring to FIGS. 1-5, if the over-current condition ceases to exist, then the power-supply controller 24 switches from the current-limit mode of operation, which is described above in conjunction with FIG. 5, to the normal mode of operation, which is described above in conjunction with FIGS. 2-4.

Referring to FIGS. 1-4, the operation of the power supply 10 while in the normal mode is described over a switching period T, according to an embodiment.

At the time t₀, the PWM controller 34 transitions the control signal 38 to a logic-high level, thus turning the transistor 36 “on”.

During the portion T_(on) of the switching period T from the time t₀ to the time t₁, the transistor 36 conducts the linearly ramping current I_(switch)=I_(in) through the inductor 18, and, therefore, “charges” the inductor with magnetic energy.

The length of T_(on) is determined, at least in part, by the negative feedback of V_(out) to the error amplifier 32. For example, if V_(out) is lower than a level set by V_(ref), then the PWM controller 34 tends to lengthen the logic-high portion of the control signal 38 so as to lengthen T_(on), and, therefore, so as to cause V_(out) to increase toward the level set by V_(ref). Conversely, if V_(out) is higher than the level set by V_(ref), then the PWM controller 34 tends to shorten the logic-high portion of the control signal 38 so as to shorten T_(on), and, therefore, so as to cause V_(out) to decrease toward the level set by V_(ref). And although V_(out) is described as being directly coupled to the inverting node of the error amplifier 32, a feedback signal related to, but not necessarily equal to, V_(out) may be coupled to the error amplifier instead of V_(out).

At the time t₁, the PWM controller 34 transitions the control signal 38 to a low-logic level so as to turn off the transistor 36, and, therefore, so as to cause I_(switch) to fall rapidly from its peak level I_(peak) to zero.

But, still at time t₁, because the inductor 18 is conducting I_(switch)=I_(in) having a level of I_(peak) immediately before the PWM controller 34 turns “off” the transistor 36, the current I_(in) through the inductor does not rapidly fall to zero because, as is known, the current through an inductor does not change instantaneously.

Instead, starting at time t₁, the input current I_(in) through the inductor 18 flows through the diode 20 such that the output current I_(out) equals the input current I_(in), i.e., I_(out)=I_(in) (I_(out)=0 during T_(on)).

Because the power supply 10 is a boost converter, |V_(out)|>|V_(in)|.

Therefore, during the portion T_(off) of the switching period T, the current I_(out)=I_(in) through the inductor 18 decays, where the rate of decay is related to the difference V_(out)−V_(in), which is the voltage across the inductor, with the assumption that the voltage across the diode 20 is comparatively negligible. Although the current I_(out)=I_(in) may decay to zero at some time during the cycle portion T_(off), it typically does not decay to zero such that, due to the filtering action of the inductor 18 and the capacitor 32, I_(Load) equals the average of I_(out), i.e., I_(Load)=I_(out) _(—) _(avg).

While operating in the normal mode, the power supply 10 repeats the above steps for each subsequent switching period T.

Referring to FIGS. 1 and 5, the operation of the power supply 10 while in the current-limiting mode is described over a switching period T, according to an embodiment.

At the time t₀, the PWM controller 34 transitions the control signal 38 to a logic-high level, thus turning the transistor 36 “on”.

During the portion T_(on) of the switching period T from the time t₀ to the time t₁, the transistor 36 conducts the linearly ramping current I_(switch)=I_(in) through the inductor 18, and, therefore, “charges” the inductor with magnetic energy.

But unlike while operating in the normal mode, the power-supply controller 24 does not determine the length of T_(on) by the negative feedback of V_(out) to the error amplifier 32, because this would allow I_(switch)=I_(in) to exceed a safe value. Consequently, while operating in the current-limiting mode, the switching regulator 28 does not regulate V_(out); that is, V_(out) is free to change from, and typically does change from, its regulated level.

Therefore, the current limiter 30 instead limits the peak level of I_(switch)=I_(in) to I_(limit) independently of the level of V_(out). In more detail, the current sensor 40 converts the voltage across the conduction nodes of the transistor 36 (this voltage being proportional to I_(switch)=I_(in)) into a current-sense signal, which the current comparator 42 receives at its non-inverting (“+”) node. When the current-sense signal becomes greater than CL_(ref), the comparator 42 transitions its output signal from a logic-low level to a logic-high level, which causes the PWM controller 34 to transition the control signal 38 to a logic-low level, and, therefore, causes the PWM controller to turn off the transistor 36. That is, the current limiter 30 limits the duty cycle D of the signal 38 such that the peak levels of I_(switch) and I_(in) do not exceed I_(limit), where D=T_(on)/T.

Still referring to FIGS. 1 and 5, at the time t₁, the PWM controller 34 transitions the control signal 38 to a low-logic level in response to the current limiter 30 so as to turn off the transistor 36, and, therefore, so as to cause I_(switch) to decrease rapidly from the current-limit threshold I_(limit) to zero.

But, still at time t₁, because the inductor 18 is conducting I_(switch)=I_(in) having a level of I_(limit) immediately before the PWM controller 34 turns “off” the transistor 36, the current I_(in) through the inductor does not fall to zero because, as is known, the current through an inductor does not change instantaneously.

Therefore, starting at the time t₁, the current I_(in) through the inductor 18 flows through the diode 20 as the current I_(out), such that I_(out)=I_(in).

Even though the power supply 10 is a boost converter, whether |V_(out)|>|V_(in)| during the current-limiting mode depends on the severity of the over-current condition (e.g., a true short circuit between the output node 14 and the reference node 26 (where the reference node is a ground node) would render V_(out)=0). But for purposes of example, it can be assumed that in most cases, even though during the current-limiting mode V_(out) may decrease from its regulated level, |V_(out)|>|V_(in)| still holds true, at least during the current-limiting action of the power supply 10.

Therefore, during the portion T_(off) of the switching period T, the current I_(out)=I_(in) through the inductor 18 decays, where the rate of decay is related to V_(out)−V_(in), which is the voltage across the inductor, with the assumption that the voltage across the diode 20 is comparatively negligible. Whether the current I_(out)=I_(in) decays to zero at some time during the portion T_(off) of the period T depends on the cause of the overcurrent condition. But in many cases, I_(out)=I_(in) does not decay to zero during T_(off) such that due to the filtering action of the inductor 18 and the capacitor 22, I_(load) equals the average of I_(out), just as it does during the normal mode of operation.

Still referring to FIGS. 1 and 5, the power supply 10 repeats the above steps for each subsequent switching period T while the overcurrent condition persists.

If the overcurrent condition ends, then the power supply 10 transitions to the normal mode of operation as described above in conjunction with FIGS. 1-4. In more detail, if the overcurrent condition ends, then the output voltage V_(out) increases to its regulated level, and this increase in V_(out) decreases the duty cycle D of the control signal 38 such that the peak level I_(peak) (FIG. 5) of I_(switch)=I_(in) also decreases. As the peak level I_(peak) (FIG. 5) of I_(switch)=I_(in) decreases, the level of the current-sense signal from the current sensor 40 decreases to below CL_(ref) such that the comparator 42 no longer transitions its output signal to a logic-high level. Therefore, control of the duty cycle D of the control signal 38 shifts from the current limiter 30 back to the feedback loop that includes the error amplifier 32.

FIG. 6A is a time plot of V_(in) and V_(out) of FIG. 1 while the power supply 10 is operating in the normal mode and in the current-limiting mode, and where V_(in)=5 V, I_(Limit)=5 A, and the supply regulates V_(out) to 16 V while operating in the normal mode, according to an embodiment.

FIG. 6B is a time plot of the current I_(in) through the inductor 18, and of the current I_(Load) through the load 12, while the power supply 10 of FIG. 1 is operating as described above in conjunction with FIG. 6A, according to an embodiment.

Similarly, FIG. 7A is another time plot of V_(in) and V_(out) of FIG. 1 while the power supply 10 is operating in the normal mode and in the current-limiting mode, and where V_(in)=5 V, I_(Limit)=5 A, and the supply regulates V_(out) to 6 V while operating in the normal mode, according to an embodiment.

And FIG. 7B is another time plot of the currents I_(in) and I_(Load) while the power supply 10 of FIG. 1 is operating as described above in conjunction with FIG. 5A, according to an embodiment.

Referring to FIGS. 1-7B, a potential problem with the above-described current-limiting technique employed by the power supply 10 is that the level to which the supply limits I_(Load) may vary depending upon power-supply design factors such as the level of V_(in) and the boost ratio V_(out)/V_(in).

Unfortunately, this dependence of the current-limited level of I_(Load) on such factors may be undesirable, because, to prevent damage to the load 12, a user of the power supply 10 may want the supply to limit I_(Load) to a settable, or to at least a predictable, value that is independent of power-supply design factors.

For example, referring to FIGS. 1-6B, at a time t₀ of FIGS. 6A-6B the power supply 10 begins operating, at a time t₁ of FIGS. 6A-6B, the supply begins to boost V_(out) to a level that is greater than the level of V_(in), and at a time t₂ of FIGS. 6A-6B, the supply attains steady-state operation in the normal mode, during which the supply maintains V_(out)=16 V, I_(peak)≈4.2 A, and I_(Load)≈3.6 A—note that I_(peak) is the actual peak level of I_(in) while the supply is operating in the normal mode.

But at a time t₃ of FIGS. 6A-6B, the power supply 10 begins to operate in the current-limiting mode in response to an overcurrent condition, such that the power-supply controller 24 causes V_(out) to droop to about 10 V, limits the peak level of the current I_(in) to I_(Limit)=5 A, and limits I_(Load) to approximately 2 A—note that I_(Limit) is the actual peak level of I_(in) while the supply is operating in the current-limiting mode.

Similarly, referring to FIGS. 1-5 and 7A-7B, at a time t₀ of FIGS. 7A-7B, the power supply 10 begins operating, at a time t₁ of FIGS. 7A-7B, the supply begins to boost V_(out) to a level that is greater than the level of V_(in), and at a time t₂ of FIGS. 7A-7B, the supply attains steady-state operation in the normal mode, during which the supply maintains V_(out)=6 V, I_(peak)≈1.5 A, and I_(Load)≈1.0 A—note that I_(peak) is the actual peak level of I_(in) while the supply is operating in the normal mode.

But at a time t₃ of FIGS. 7A-7B, the power supply 10 begins to operate in the current-limiting mode in response to an overcurrent condition, such that the power-supply controller 24 causes V_(out) to droop to approximately 5.5 V, limits the peak level of I_(in) to I_(Limit)=5 A, and limits I_(Load) to approximately 3.5 A—note that I_(Limit) is the actual peak level of I_(in) while the supply is operating in the current-limiting mode.

Referring to FIGS. 6A-7B, although while operating in the current-limiting mode the power-supply controller 24 limits the peak level of I_(switch)=I_(in) to I_(Limit)=5 A in both examples, the controller 24 limits I_(Load) to a significantly different level (i.e., approximately 2 A and 3.5 A, respectively) in each example.

Furthermore, although in the first example the power-supply controller 24 limits I_(Load) to a current-limiting-mode level (i.e., to approximately 2 A) that is less than its normal-mode level (i.e., approximately 3.6 A), in the second example, the controller 24 limits I_(Load) to a current-limiting-mode level (i.e., approximately 3.5 A) that is significantly higher than its normal-mode level (i.e., approximately 1 A).

Unfortunately, the inconsistent limiting of I_(Load) illustrated by the two above-described examples may be a problem for a user of the power supply 10. Although such a user may like to know the peak-limit threshold I_(Limit) to which the power-supply controller 24 limits the switch and input currents I_(switch) and I_(in) while the power supply 10 is operating in the current-limiting mode, it is typically more important to the user that he/she know, or at least be able to predict, the level to which the controller 24 limits I_(Load).

Referring again to FIG. 1, a technique that the power-supply controller 24 could employ for limiting I_(Load) to a predictable level while the power supply 10 is operating in a current-limiting mode would be to monitor I_(Load), and to limit I_(Load) to a set threshold level.

But this technique may require the power-supply controller 24 to include an additional pin for receiving I_(Load), or for receiving a signal that is related to I_(Load), and may require the power supply 10 to include additional circuitry (e.g., a Hall-Effect sensor) for sensing I_(Load).

Unfortunately, including an additional pin may increase the cost, footprint, or complexity, or decrease the efficiency, of the power-supply controller 24, and including additional circuitry may increase the cost, footprint, or complexity, or decrease the efficiency, of the power supply 10.

Still referring to FIG. 1, an embodiment of a technique for limiting I_(Load) to a settable, or at least predictable, level entails limiting I_(switch), and, therefore, limiting I_(in) and I_(Load), in response to the boost ratio V_(out)/V_(in) of the power supply 10, or in response to a quantity that is related to the boost ratio.

From the theory of conservation of energy, it is also known that the power into an ideal converter, such as an ideal version of the power supply 10, equals the power out of the ideal converter (because there are no losses in an ideal converter) according to the following equation:

V _(in) ·I _(in) _(—) _(avg) =V _(out) ·I _(out) _(—) _(avg)  (1)

And assuming that the load 12 is purely resistive, due to the filtering action of the output filter capacitor 22, one can assume that I_(our) _(—) _(avg)=I_(Load) in a steady state. Therefore, from equation (1), one can derive the following mathematical relations between I_(in) _(—) _(avg) and I_(Load):

I _(in) _(—) _(avg) /I _(Load) =V _(out) /V _(in)=Boost_Ratio  (2)

I _(Load) =I _(in) _(—) _(avg)·(V _(in) /V _(out))=I _(in) _(—) _(avg)/Boost_Ratio  (3)

And although the power supply 10 of FIG. 1 is not an ideal supply, the value of I_(Load) given by these equations is accurate enough for purposes of current limiting.

Therefore, as further described below, because I_(in) _(—) _(avg), V_(in), and V_(out) are already received by, or determinable from, existing pins of the power-supply controller 24 of FIG. 1, one may be able to configure the power-supply controller and the power supply 10 of FIG. 1 to employ a current-limiting technique that uses the power-supply boost ratio with little or no increase in the cost, footprint, or complexity, and with little or no decrease in the efficiency, of the controller or supply.

Furthermore, it is also known that for an ideal version of the boost power supply 10 of FIG. 1:

V _(out) /V _(in)=Boost_Ratio=1/(1−D)  (4)

-   -   where D=T_(on)/T is the duty cycle of the control signal 38,         which drives the switching transistor 36.

Similarly for an ideal version of a buck-boost power supply (not shown)

V _(out) /V _(in)=Boost Ratio=D/(1−D)  (5)

FIG. 8 is a plot 60 of the Boost_Ratio versus the duty cycle D for an ideal version of the boost power supply 10 of FIG. 1, and a plot 62 of the boost ratio versus the duty cycle for an ideal version of a buck-boost power supply (not shown), according to equations (4) and (5), respectively, for 0 D<1.

From equations (3) and (4), one can derive the following equation for an ideal version of the boost power supply 10 of FIG. 1:

I _(load)=(1−D)·I _(in) _(—) _(avg)=(1−D)·(I _(valley)+(I _(peak) −I _(valley))/2)  (6)

Referring to FIG. 1 and equation (6), because the PWM controller 34 generates the control signal 38, the duty cycle D is also available to the power-supply controller 24 as a quantity related to the Boost_Ratio.

FIG. 9 is an embodiment of a power supply 70, which is configured to employ a technique for limiting I_(Load) to a settable, or at least to a predictable, level in response to the Boost_Ratio=V_(out)/V_(in) of the power supply, or in response to a quantity that is related to the Boost_Ratio, according to an embodiment. As described below, the power supply 70 so limits I_(Load) by limiting the peaks of I_(switch) and I_(in) in response to the Boost_Ratio, or in response to a quantity that is related to the Boost_Ratio. Furthermore, each component of the power supply 70 that is similar to a respective component of the power supply 10 of FIG. 1 is labeled with the same reference number in both FIGS. 1 and 9, and is not described again for the sake of brevity.

The power supply 70 of FIG. 9 includes a power-supply controller 72, which, in addition to the switching regulator 28, includes a current limiter 74.

In addition to the comparator 42, the current limiter 74 includes a current-limit controller 76, which includes the current sensor 40, and which receives, in addition to the voltage across the transistor 36, V_(in), V_(out), and the PWM control signal 38.

Therefore, while the power supply 70 is operating in a current-limiting mode, the power-supply controller 72 may determine the level of I_(Load) according to equation (3), and generate and vary CL_(ref) in response to the determined value of I_(Load) so as to limit I_(Load) to a set threshold level. For example, if I_(Load) is to be limited to 1 A, but the initial set switch current limit threshold is I_(Limit)=5 A, then in response to the conditions of operation, the power-supply controller 72 is configured to adjust (e.g., to lower) the level of CL_(ref). The power-supply controller 72 continues adjusting CL_(ref), determining the level of I_(Load) per equation (3), and monitoring this level until the load current is less than or equal to the threshold limit level of 1 A. That is, the controller 72 uses negative feedback of I_(in), V_(out), and V_(in) to adjust the peak levels of I_(switch) and I_(in) until the level of I_(Load) obtained by solving equation (3) is less than or equal to the threshold limit level, which is 1 A in the above example.

Still referring to FIG. 9, alternatively, the power-supply controller 72 may determine the level of I_(Load) according to equation (6), and generate and vary (e.g., lower) CL_(ref) in response to the determined level of I_(Load) so as to limit I_(Load) to the threshold limit level. For example, if I_(Load) is to be limited to 1 A, but the switch limit level is I_(Limit)=5 A, then the power-supply controller 72 adjusts the level of CL_(ref), which adjusts (e.g., reduces) T_(on), and, therefore, the duty cycle D, of the control signal 38 by adjusting the time during the period T when the comparator 42 transitions its output to a logic-high level. The power-supply controller 72 continues adjusting CL_(ref), determining a level for I_(Load) per equation (6), and monitoring this determined level until the determined level is less than or equal to the threshold level 1 A. That is, the power-supply controller 72 uses feedback of I_(in) and the duty cycle D to adjust I_(in) until the level of I_(Load) obtained by solving equation (6) is less than or equal to the threshold limit level.

The power-supply controller 72 may determine the values of I_(valley) and I_(peak) in equation (6) by measuring the voltages across the transistor 36 at respective times t₀ and t₁ of FIGS. 2-4 and by dividing these voltages by the on resistance RDS_(on) of the transistor. Alternatively, because the difference I_(peak)−I_(valley) may be considered negligible compared to I_(valley), the power-supply controller 72 may approximate I_(in) _(—) _(avg) as being equal either to I_(valley) or to I_(peak), or to (I_(peak)−I_(valley))/2. Furthermore, there are other conventional techniques for determining I_(in) _(—) _(avg) that the power-supply 72 may employ.

Referring to FIGS. 2-5 and 9, the operation of the power supply 70 is described, according to an embodiment.

Referring to FIGS. 2-4 and 9, while the power supply 70 is operating in a normal mode, it operates in a manner similar to the manner in which the power supply 10 of FIG. 1 operates while in a normal mode as described above in conjunction with FIGS. 1-4.

Referring to FIGS. 5 and 9, while operating in a current-limit mode, the power supply 70 limits I_(Load) to a threshold level without directly sensing I_(Load).

When the power supply 70 first enters the current-limiting mode, the current limiter 74 limits the peak levels of I_(switch) and I_(in) to I_(Limit) as described above in conjunction with FIGS. 1 and 5.

Furthermore, the current-limit controller 76 determines a level for I_(Load) per equation (3) or equation (6). For example, if determining a level for I_(Load) per equation (3), then the controller 76 may include circuitry that calculates I_(in) _(—) _(avg)=(I_(valley)+(I_(Limit)−I_(valley))/2), and that divides V_(out) by V_(in) to calculate the Boost_Ratio. Alternatively, if determining a level for I_(Load) per equation (6), then the controller 76 may include circuitry that calculates I_(in) _(—) _(avg)=(I_(valley)+(I_(Limit)−I_(valley))/2), calculates the duty cycle D by dividing the time T_(on) by the period T, and calculates 1−D.

Next, the current-limit controller 76 compares the level determined for I_(Load) to the load-current limit threshold.

If the level determined for I_(Load) is less than or equal to the load-current limit threshold, then the current-limit controller 76 maintains CL_(ref) at its current level.

But if the level determined for I_(Load) is greater than the load-current limit threshold, then the current-limit controller 76 adjusts (e.g., lowers) the level of CL_(ref) as needed to reduce I_(Load); the controller 76 may using a dithering technique to determine whether raising or lowering the level of CL_(ref) reduces I_(Load), and may adjust the level of C_(Lref) in steps, or according to a continuous slope, to prevent oscillation.

Then, the current-limit controller 76 continues to determine a level for I_(Load), to compare this level to the load-current limit threshold, and to adjust the level of CL_(ref) until the determined level of I_(Load) is less than or equal to the load-current limit threshold.

If the cause of the overcurrent condition is removed, then I_(Load) will decrease to below the load-current limit threshold, and in response, the current-limit controller 76 will set the level of CL_(ref) back to its normal-mode level.

Still referring to FIGS. 5 and 9, alternate embodiments of the current-limit mode are contemplated. For example, the actions described above may be performed in any suitable order, one or more of the actions may be omitted, and one or more other actions may be added.

Referring to FIGS. 9 and 10, an embodiment of the power supply 70 that uses only the duty cycle D to adjust CL_(ref) is described, according to an embodiment.

FIG. 10 is a diagram of a circuit 80, which is configured to generate CL_(ref) in response to the duty cycle D of the control signal 38, and which may be disposed on the current-limit controller 76 of FIG. 9, according to an embodiment.

The circuit 80 includes a filter stage 82, a comparator stage 84, a decoder stage 86, and a reference-generator stage 88.

The filter stage 82 converts the control signal 38 into its average DC value, which is proportional to the duty cycle D.

The comparator stage 84 includes one or more comparators 90 (here three comparators) that each compare the DC value of the control signal 38 from the filter stage 82 to a respective reference voltage VREF (these reference voltages may be different than the reference voltage V_(ref) of FIG. 9).

The decoder stage 86 receives the one or more comparator-generated output signals from the comparator stage 84, and generates, in response to these one or more output signals, one or more control signals 92.

The reference-generator stage 88 includes one or more switches 94, which couple a voltage that corresponds to the one or more control signals 92 to a CL_(ref) node 96; that is, CL_(ref) equals the voltage that the stage 88 couples to the node 96. In an embodiment, the one or more voltages that the switches 94 may couple to the node 96 are generated by a resistive voltage divider 98 and another reference voltage VREF (this reference voltage may be different than the reference voltage V_(ref) of FIG. 9 and the reference voltages VREF of the comparator stage 84).

Referring to FIGS. 2-4 and 9-10, while in the normal mode, the power supply 70 operates in a manner similar to manner in which the power supply 10 of FIG. 1 operates during the normal mode as described above in conjunction with FIGS. 1-4.

Referring to FIGS. 5 and 9-10, while the power supply 70 is operating in the current-limiting mode, the circuit 80 adjusts CL_(ref) in response to the duty cycle D of the control signal 38 so as to cause I_(Load) to be less than or equal to the load-current limit threshold. If the overcurrent condition ends, then the duty cycle D returns to its steady-state-normal-operation value, and, in response, the circuit 80 returns CL_(ref) to its normal-operation level. Referring to FIG. 5, even though in this embodiment I_(load) is not determined in response to I_(in) _(—) _(avg), the duty cycle D increases in response to the overcurrent condition because I_(limit) (FIG. 5) is greater than the normal-mode level of I_(peak) (FIGS. 2-4). Therefore, when D increases beyond a threshold level set by the circuit 80, this circuit adjusts CL_(ref) so as to reduce I_(Lead) to a lower, more predictable, level.

Two examples that illustrate that the power supply 70 of FIG. 9 can limit I_(Load) to a predictable, or a settable, threshold limit are described below in conjunction with FIGS. 11A-12B, according to an embodiment.

FIG. 11A is a time plot of V_(in) and V_(out) of FIG. 9 while the power supply 70 is operating in the normal mode and in the current-limiting mode, and where V_(in)=5 V, I_(limit) (the limit threshold for the peaks of I_(switch) and I_(in))=5 A, the load-current limit threshold for I_(Load) is 1.5 A, and the supply regulates V_(out) to 16 V while operating in the normal mode, according to an embodiment.

FIG. 11B is a time plot of the current I_(in) through the inductor 18, and of the current I_(Load) through the load 12, while the power supply 70 of FIG. 9 is operating as described above in conjunction with FIG. 11A, according to an embodiment.

Similarly, FIG. 12A is a time plot of V_(in) and V_(out) of FIG. 9 while the power supply 70 of FIG. 9 is operating in the normal mode and in the current-limiting mode, and where V_(in)=5 V, I_(limit)=5 A, the load-current limit threshold for I_(Load) is 1.5 A, and the supply regulates V_(out) to 6V while operating in the normal mode, according to an embodiment.

And FIG. 12B is a time plot of the currents I_(in) and I_(load) while the power supply 70 of FIG. 9 is operating as described above in conjunction with FIG. 12A, according to an embodiment.

For example, referring to FIGS. 2-4, 9, and 11A-11B, at a time t₀ of FIGS. 11A-11B, the power supply 70 begins to operate, at a time t₁ of FIGS. 11A-11B, the supply begins to boost V_(out) to a level that is greater than the level of V_(in), and at a time t₂ of FIGS. 11A-11B, the supply attains a steady-state operation in the normal mode, during which it maintains V_(out)=16 V, I_(peak)≈4.2 A, and I_(load)≈13.6 A.

But at a time t₃ of FIGS. 11A-11B, referring also to FIGS. 5 and 9, the power supply 70 begins to operate in the current-limiting mode in response to an overcurrent condition, such that the power-supply controller 72 causes V_(out) to droop to about 8 V, initially limits the peak levels of the switch and input currents I_(switch) and I_(in) to I_(Limit)=5 A, and then limits the peak levels of the switch and input currents I_(switch) and I_(in) to approximately 3 A as the current limiter 74 limits I_(Load) to the set threshold of 1.5 A.

Similarly, referring to FIGS. 2-4, 9, and 12A-12B, at a time t₀ of FIGS. 12A-12B, the power supply 70 begins to operate, at a time t₁ of FIGS. 12A-12B the supply begins to boost V_(out) to a level that is greater than the level of V_(in), and at a time t₂ of FIGS. 12A-12B, the supply attains steady-state operation in the normal mode, during which the supply maintains V_(out)=6 V, I_(peak)≈1.5 A, and I_(load)≈11.0 A.

But at a time t₃ of FIGS. 12A-12B, referring also to FIGS. 5 and 9, the power supply 70 begins to operate in the current-limiting mode in response to an overcurrent condition, such that the power-supply controller 24 causes V_(out) to droop to approximately 5.5 V, limits the peak levels of the switch and input currents I_(switch) and I_(in) to I_(Limit)≈2 A, and limits I_(Load) the load-current limit threshold of 1.5 A.

Therefore, referring to FIGS. 11A-12B, unlike the power supply 10 of FIG. 1, the power supply 70 of FIG. 9 limits I_(Load) to the limit threshold of 1.5 A independently of power-supply-design and power-supply-implementation factors such as V_(in), V_(out), the peak switch/input current limit I_(Limit), and the Boost_Ratio=V_(out)/V_(in).

Referring to FIGS. 9-12B, alternate embodiments of the power supply 70 are contemplated. For example, the power-supply controller 72 may be implemented in hardware, firmware, or software, or in any combination of or sub-combination thereof. Furthermore, the current-limit controller 72 may not receive V_(out) and V_(in) if it uses only the duty cycle D of the control signal 38 to limit I_(switch), I_(in), and I_(Load) in the current-limit mode, and may not receive the control signal 38 if it uses only the Boost_Ratio=V_(out)/V_(in) to limit I_(switch), I_(in), and I_(Load) in the current-limit mode. Moreover, the current-limit controller 76 may use quantities that are related to the Boost_Ratio other than the duty cycle D to limit I_(switch), I_(in), and I_(Load) during the current-limit mode of operation. In addition, a power supply having a topology other than a boost-converter topology (e.g., a buck-boost topology, or a flyback topology where I_(Load)=[(1−D)/D]·I_(in) _(—) _(avg)) may employ one of the above-described embodiments for limiting I_(switch), I_(in), and I_(Load).

FIG. 13 is a block diagram of an embodiment of a computer system 100, which incorporates the power supply 70 of FIG. 9, according to an embodiment. Although the system 100 is described as a computer system, it may be any system for which an embodiment of the power supply 70 is suited.

The system 100 includes computing circuitry 102, which, in addition to the supply 10, includes a processor 104 powered by the supply, at least one input device 106, at least one output device 108, and at least one data-storage device 110.

In addition to processing data, the processor 104 may program or otherwise control the supply 70. For example, the functions of the power-supply controller 72, PWM controller 34, and current-limit controller 76 (FIG. 9) may be performed by the processor 104.

The input device (e.g., keyboard, mouse) 106 allows the providing of data, programming, and commands to the computing circuitry 102.

The output device (e.g., display, printer, speaker) 108 allows the computing circuitry 102 to provide data in a form perceivable by a human operator.

And the data-storage device (e.g., flash drive, hard disk drive, RAM, optical drive) 110 allows for the storage of, e.g., programs and data.

From the foregoing it will be appreciated that, although specific embodiments have been described herein for purposes of illustration, various modifications may be made without deviating from the spirit and scope of the disclosure. Furthermore, where an alternative is disclosed for a particular embodiment, this alternative may also apply to other embodiments even if not specifically stated. Moreover, the components described above may be disposed on a single or multiple IC dies to form one or more ICs, these one or more ICs may be coupled to one or more other ICs. In addition, any described component or operation may be implemented/performed in hardware, software, firmware, or a combination of any two or more of hardware, software, and firmware. Furthermore, one or more components of a described apparatus or system may have been omitted from the description for clarity or another reason. Moreover, one or more components of a described apparatus or system that have been included in the description may be omitted from the apparatus or system. 

1. A power-supply controller, comprising: a switching regulator configured to generate an input current such that an output voltage is generated in response to the input current and an input voltage; and a current limiter configured to limit the input current in response to a quantity that is related to a ratio of the output voltage divided by the input voltage.
 2. The power-supply controller of claim 1 wherein the switching regulator is configured to generate a control signal for controlling a power-supply switch that is configured to conduct the input current.
 3. The power-supply controller of claim 2, further comprising the power-supply switch.
 4. The power-supply controller of claim 2, wherein the quantity includes the control signal.
 5. The power-supply controller of claim 2, wherein the quantity includes a duty cycle of the control signal.
 6. The power-supply controller of claim 2, wherein the quantity includes unity minus a duty cycle of the control signal.
 7. The power-supply controller of claim 2, wherein the quantity includes a difference divided by a duty cycle of the control signal, the difference being equal to unity minus the duty cycle.
 8. The power-supply controller of claim 1, wherein the quantity equals the ratio of the output voltage divided by the input voltage.
 9. The power-supply controller of claim 2, wherein the quantity includes a signal having a level that is related to a duty cycle of the control signal.
 10. A power supply, comprising: an input node configured to receive an input voltage; an output node configured to carry an output voltage; a switch configured to conduct an input current from the input node in response to a control signal; and a power-supply controller, including a switch controller configured to generate the control signal, and a current limiter configured to limit the input current in response to a quantity that is related to a ratio of the output voltage divided by the input voltage.
 11. The power supply of claim 10 wherein the switch includes a transistor having a control node configured to receive the control signal.
 12. The power supply of claim 10, further comprising: an inductor coupled between the input node and the switch and configured to conduct the input current during a first portion of a cycle of the switch and to conduct a discharge current during a second portion of the cycle; and a unidirectional-current device coupled between the inductor and the output node and configured to conduct the discharge current during the second portion of the cycle.
 13. The power supply of claim 10, further comprising: a reference node; an inductor coupled between the input node and the switch and configured to conduct the input current during a first portion of a cycle of the switch and to conduct a discharge current during a second portion of the cycle; a unidirectional-current device coupled between the inductor and the output node and configured to conduct the discharge current during the second portion of the cycle; and a capacitor coupled between the output node and the reference node.
 14. A system, comprising: a power supply, including an input node configured to receive an input voltage, an output node configured to carry an output voltage, a switch configured to conduct an input current from the input node in response to a control signal, and a power-supply controller, including a switch controller configured to generate the control signal, and a current limiter configured to limit the input current in response to a quantity that is related to a ratio of the output voltage divided by the input voltage; and a load coupled to the output node of the power supply.
 15. The system of claim 14 wherein the power supply includes a boost converter.
 16. The system of claim 14 wherein the load includes an integrated circuit.
 17. The system of claim 14 wherein the load and a portion of the power supply are disposed on a same integrated-circuit die.
 18. The system of claim 14 wherein the load and a portion of the power supply are disposed on respective integrated-circuit dies.
 19. The system of claim 14 wherein: the load is configured to conduct a load current; and the current limiter is configured to limit the load current in response to the quantity.
 20. A method, comprising: generating an output voltage in response to an input voltage and an input current; and limiting the input current in response to a quantity that is related to a ratio of the output voltage over the input voltage.
 21. The method of claim 20 wherein: generating the output voltage includes periodically causing the input current to flow according to a duty cycle; and the quantity is related to the duty cycle.
 22. The method of claim 20 wherein generating the output voltage includes causing the output voltage to have a magnitude that is greater than a magnitude of the input voltage.
 23. The method of claim 20, further comprising limiting an output current in response to the quantity.
 24. A method, comprising: generating an output voltage and an output current in response to an input voltage; and limiting the output current in response to a quantity that is related to a ratio of the output voltage over the input voltage.
 25. The power-supply controller of claim 1 wherein the output voltage includes a regulated output voltage.
 26. The power-supply controller of claim 1 wherein the output voltage is not galvanically isolated from the input voltage.
 27. The power-supply controller of claim 1 wherein the switching regulator is configured to generate the input current such that the input current flows from the input voltage to the output voltage.
 28. The power supply of claim 10 wherein the output voltage includes a regulated output voltage.
 29. The power supply of claim 10 wherein the output node is not galvanically isolated from the input node.
 30. The power supply of claim 10 wherein the switch is configured: to conduct the input current from the input node in response to the control signal having a first value; and to allow the input current to flow to the output node in response to the control signal having a second value.
 31. The system of claim 14 wherein the output voltage includes a regulated output voltage.
 32. The system of claim 14 wherein the load is not galvanically isolated from the input node.
 33. The system of claim 14 wherein the switch is configured: to conduct the input current from the input node in response to the control signal having a first value; and to allow the input current to flow to the load in response to the control signal having a second value.
 34. The method of claim 20 wherein the output voltage includes a regulated output voltage.
 35. The method of claim 20 wherein the output voltage is not galvanically isolated from the input current.
 36. The method of claim 20 wherein generating the output voltage includes causing the input current to flow to the output voltage.
 37. The method of claim 24 wherein the output voltage includes a regulated output voltage.
 38. The method of claim 24 wherein the output current is not galvanically isolated from the input voltage.
 39. The method of claim 24 wherein generating the output voltage includes causing the output current to flow from the input voltage. 